Synchronizing device



Aug. 10, 1937. E. w. SWANSON ,0

SYNCHRONIZ ING DEVI CE Filed May 4, 1936 5 Sheets-Sheet l c T \C/ECUIT' INVENTOR- fZM/Yh/JWA/YJO/Y Je/ZCZUMMM/ HIS ATTORNEY Aug. 10, 1937. E. w. SWANSON SYNCHRONIZING DEVICE Filed- May 4, 1956 3 Sheets-Sheet 2 MW m m m Vm m M m m Y B 1937- E. W. SWANSON 2,089,448

SYNCHRONI Z ING DEVICE Filed May 4, 1936 5 Sheets-Sheet 3 a4? 6 A ,4-c.

C/ECU/T 0 Y1 INVENTOR. EOI W/Y W JIM/760A MGM 19/6 A TTORNEY Patented Aug. 10, 1937 UNITED STATES PATENT OFFICE SYNCHRONIZING DEVICE Minneapolis, Minn.

Application May 4, 1936, Serial No. 77,765

13 Claims.

My invention relates to synchronizing devices for automatically paralleling sources of alternating current and has for an object to provide a synchronizing device which is inexpensive and simple in construction.

Another object of the invention resides in providing a synchronizing device which is extremely positive in action and reliable in operation.

A still further object of the invention resides in providing a synchronizing device which has a minimum number of moving parts and which will not readily get out of order.

Another object of the invention resides in providing a synchronizing device which does not require an expert to install, adjust, or operate it.

An object of the invention resides in providing a synchronizing device in which the paralleling operation of one source of alternating current to the other is initiated at a positively fixed predetermined angle in advance of phase coincidence. I

In carrying out the objects of my invention, I utilize a magnetic core having three magnetic paths, one of the paths being constructed with an air gap adapted to be closed by a movable armature, and arranged with windings on two of the portions of the said core forming the other two paths and connected to the sources of alternating current so as to cause flux to flow through said air gap when the voltages of the sources are out of phase and differ in frequency and connected so as to cause substantially complete elimination of flux through the air gap when the voltages are substantially alike in frequency and phase.

- My synchronizing device is applicable to singlephase, three-phase, and other polyphase electric systems without change, but for the sake of simplicity it will be shown and illustrated for use only with a three-phase system.

These and other objects and advantages of the invention will be fully set forth in the following description made in connection with the accompanying drawings, in which like reference characters refer to similar parts throughout th several views, and in which:

Fig. 1 is a wiring diagram of a synchronizing device illustrating an embodiment of my invention.

Fig. 2 is a diagrammatic view of the synchronizer shown in Fig. 1 with the armature in one position.

Fig. 3 is a view similar to Fig. 2 showing the armature in another position.

Fig. 4 is a vector diagram showing the relation of the Various voltages occuring in the operation of my synchronizing device.

Fig. 5 is a conventional representation of an oscillogram of the voltages shown in Fig. 4, before, during and after the paralleling operation.

Fig. 6 is a view similar to Fig. 3 of another form of synchronizer.

Fig. 7 is a wiring diagram of a modification of the invention in which the paralleling operation is initiated in advance of the occurrence of phase coincidence.

Fig. 8 is a vector diagram of the voltages involved in the modification of the invention shown in Fig. 7. y

The synchronizing device includes a novel synchronizer which I have indicated in its entirety by the reference numeral I0, together with circuit closing means or circuit breaker 3|, and actuating mechanism therefor and circuits associated therewith. These various parts of the invention will now be described in detail.

The synchronizer I0 comprises a laminated magnetic core II which is constructed with two legs I! and I8 connected together by means of ,two end pieces I" and H8. These end pieces extend outwardly beyond the leg I8 to form pole pieces H9 and I20. An armature I2 pivoted at I9 to some point fixed relative to the core II, extends across the pole pieces H9 and I28 and is adapted to swing toward and from these pole pieces to form air gaps I2I and I22 when in the position shown in Fig. 2. The armature I2 and core II are preferably arranged so that the armature drops by gravity to the position shown in Fig. 2 when no magnetic flux flows through the air gaps I2I and I22. When the armature is moved to the position shown in Fig. 3 the air gaps I2I and I22 are closed. It willbe thus seen that armature I2, air gaps I2I and I22, and pole pieces H9 and I20 form one magnetic path, that leg I8 forms a second magnetic path, and that leg I1, and end pieces I I1 and H8 form a third magnetic path. These paths have been indicated by the reference numerals H2, H4 and H3 respectively. By means of the construction utilized, two magnetic circuits are-provided. One of these circuits is shown in Fig. 3 and comprises two branch circuits 22 and 23 which are in parallel. Branch circuit 22 includes magnetic paths I I2 and I I4,while branch circuit 23 includes magnetic paths I I 2 and I I3. The other magnetic circuit is indicated at 24 and is shown in Fig. 2. This circuit includes only the magnetic paths H3 and Ill.

On the leg I1 is disposed a potential winding I3 while on the leg I8 is disposed another potential winding I4. These windings are energized by the potential of the two sources to be paralleled and are constructed so that the flux resulting from each winding is substantially the same magnitude when the voltages are equal.

Operating in conjunction with the armature I2 is a switch 5 which comprises contacts I5 and II. Contact I5 is carried by the armature I2 10 and is connected to an electric conductor on said armature which conductor in turn is connected to a flexible conductor 2|. Contact I5 is fixed. When the armature is in the position shown in Fig. 3 the switch I I5 is open. When the 15 armazture opens, the switch is closed as shown in 'For the purpose of illustrating the application of the invention, a three-phase alternating-current circuit 3 has been shown which is connected to a suitable source of three-phase alternating current not illustrated. This circuit will be hereinafter referred to as the a-c. circuit and includes three conductors a, b, and c. In addition a three-phase generator 3|! has been shown which includes an armature 33 and a field winding 32,

said field winding being energized from any suitable source of direct current, not shown. To the armature 33 is connected a three-phase circuit I consisting of three conductors A, B and C.

so This circuit is connected to the a-c. circuit 9 by means of a circuit breaker 3|, the conductors A, B and C of the generator circuit I30 being respectively connected to the conductors a, b

and c of the a-c. circuit 3. The circuit breaker 3| may be of any conventional form and is operated by an electromagnet 31 having an actuating coil I31. Since the mechanism operated by this electromagnet 31 for closing the circuit breaker does not form any feature of the invention, it has not been shown in detail and no description thereof will be given.

The method of connecting the synchronizing device to the circuits 9 and I30 will now be described in detail.

For energizing winding I4 a potential transformer 38 is employed, the primary of which is connected to the conductors b and c of the a-c. circuit 9. To the secondary of this transformer are connected conductors Ill and I42 whichare connected directly to the potential winding I4. For energizing winding I3 a similar potential transformer 34 is employed, the primary of which is connected to the conductors B and C. To the secondary of this transformer are connected conductors I43 and I44 which are similarly connected to the winding l3. Where the generator and a-c. circuit voltages are sufficiently low to accommodate the windings I3 and I4 directly, the transformers 34 and 35 may be omitted.

50 Switch 5 actuated by armature I2 of syn-- chronizer III is connected in a circuit which I have termed the synchronizing circuit. This circuit functions to close the circuit breaker 3| when the voltages of the sources of alternating current 55 to be paralleled are substantially alike in frequency and phase. This circuit will now be described in detail. Contact I5 of switch H5 is as previously stated connected to conductor 20 which in turn is connected to flexible conductor 2|. Flexible conductor 2| is connected by means of a conductor I45 with conductor I42 leading from transformer 36. Contact I6 of switch 5 is con nected by means of a conductor I46 with a switch I35 of a potential relay 35, to be presently further described. Switch I3! is connected by means of a conductor I41 to the coil I31 of electromagnet 31. A conductor I48 connects electromagnet coil I31 with a starting switch S and another conductor I43 connects this switch with the conductor |4| leading from transformer 36. When the synchronizing circuit is closed as will be hereinafter explained, electromagnet 31 becomes energized and the circuit breaker 3| closes.

The potential relay 35 includes in addition to the switch I35, an operating coil I38 which when energized closes the switch I35. This coil is connected by means of conductors |5| and I52 to the secondary of potential transformer 34.

In paralleling polyphase systems, the phase sequence of the generator voltages must be in the same rotative direction as that of the source of alternating current with which it is to be paralleled. Thus before making any attempts to synchronize the generator to the a-c. circuit, the generator connections must be so made that the phase sequence of the generator voltages corresponds to that of the a-c. circuit voltages. Since single-phase systems have only one phase voltage, this requirement obviously does not apply thereto.

The method of operation of the synchronizing device shown in Fig. 1 is as follows: Winding I4 is always connected to transformer 36 and is therefore energized by the a-c. circuit potential. Assuming that the a-c. circuit 9 is energized, the winding I4 will immediately close the armature l2 and thereby open switch 5 of synchronizer III. Switch S is normally open. Likewise winding I3 is always connected to the transformer 34. Before the generator 30 is started up this winding is not energized by transformer 34. The generator 30 is next started and brought up to near synchronous speed in the usual manner by means of its prime mover. Potential relay 35 is set to operate at a predetermined voltage which may vary as found suitable. The synchronizer I0 is so designed that winding I3 becomes effective to operate in conjunction with winding I4 to maintain armature I2 in closed position until the electrornotive forces of the generator and a-c. circuit are substantially alike in frequency and phase. Thus when the voltages of the a-c. circuit and generator are not substantially alike in frequency and phase, the armature I2 remains closed. Switch S is closed in any suitable manner, either manually or automatically, or directly or by remote control. If there is no direct-current excitation on the field winding 32 of the generator, the potential relay 35 will not close which holds the synchronizing circuit open and thereby prevents energization of the electromagnet 31 and the connection of the generator circuit to the a-c. circuit 3. If there is ample direct-current excitation on the generator, the resulting generated voltage will energize the potential relay 33 which closes its switch I35. At approximately 97% to 103% of synchronous speed, the synchronizing device will operate as soon as the electromotive forces of the generator and. circuit are substantially alike in phase relationship. Then the armature I2 drops open and closes switch ||5 which energizes the electromagnet 31 to close the circuit breaker 3| and thereby connects the generator 3 0 to the a-c. circuit 9. Thereafter normal operation occurs. To disconnect the generator from the a-c. circuit 9 and shut down its prime mover, the power to the prime mover is first reduced, then the switch S is opened which deenergizes the synchronizing circuit This opens the circuit breaker 3| and thereby disconnects the generator 30 from the a-c. circuit 9. Then the power to the prime mover is fully out ofi and the generator field winding 32 deenergized, and thereafter the generator and prime mover come to a 5 standstill.

The theory of operation of my invention will now be explained. Assume that the generator 30 is ready to be synchronized and paralleled with the a-c. circuit 9. For proper synchronizing, it is well known that the electromotive forces of the generator and circuit must be substantially alike in frequency and phase. Winding I I, being connected to the a-c. circuit, is responsive in frequency and phase to the a-c. circuit voltage, and winding I3 is similarly responsive to the generator voltage. Fig. 3 shows the synchronizing device when the electromotive forces of the generator and circuit are not alike in phase. Wind-= ing i i produces a magnetomotive force at a certain instant of time which results in flux flowing in the magnetic circuit 22 in a counterclockwise direction. Winding I3 similarly produces a magnetomotive force at the same instant of time which results in flux flowing in the magnetic circuit in the same direction. Both fluxes pass through the armature l2 and air gaps l2l and I122 and will cooperate to pull up or close the armature l2, thereby opening the switch H5. When the electromotive forces of the generator and a-c. circuit are alike in frequency and phase, the synchronizing device will operate as shown in Fig. 2. At a corresponding instant of time to that assumed above, the flux produced by winding it in magnetic path I I4 is in the same direction as before while that produced by winding I3 in magnetic path I I3 is now in a clockwise direction. The resultant flux will then flow in magnetic circuit 24 in a clockwise direction. Due to the reversal of direction of the flux produced by 40 winding I3 there will be substantially complete elimination of flux in armature I2 and the force of gravity will open the armature I2 so as to close the switch H5 which operates to close the synchronizing circuit as heretofore described.

For a better understanding of the operation of the invention under varying conditions, reference is to be had to Fig. i in which the various voltages are represented vectorially. For the purpose of discussion it will be assumed that the 50 ac. circuit voltage is equal to the generator voltage.

At a certain instant of time the a-c. circuit voltage and the generator voltage would have a certain phase relation. These voltages are repre- 55 sented by the vectors OC and G. At certain I other instants of time these voltages would have different phase relations. If the a-c. circuit voltage vector is assumed to be fixed at DC, the generator voltage vector would rotate about 0 60 as a center, the locus of the point G of said vector being the circle GACD. The synchroniz ng device will operate to close its armature l2 on an adjustable'voltage CD, equal for instance to approximately 65% of normal voltage. Since they 35 generator voltage 0G may notbe equal to the a-c. circuit voltage 00 when synchronizing is desired, the point D will not always lie on the generator circle GACD. The locus of point D of I voltage CD is shown by circle NDHM. The same 7 device will operate to drop or open its armature l2 at a lower voltage than CD, such as voltage CA and its locus may be shown by circle FABE. Perfect paralleling operation occurs when the gen erator voltage 0G coincides with the a-c. circuit 75 voltage DC. I have referred to the voltage corresponding to the flux produced in armature I2 as the synchronizing voltage.

At all times this synchronizing voltage is equal to the vector difference of the circuit voltage 00 and the generator voltage 0G. Assuming the generator voltage 0G to revolve in a clockwise direction when the generator is operating below synchronous speed and beginning at the position when 0G is at OD, the synchronizing voltage CD will operate to close the armature I2 and thereby hold open the switch il5. When the generator voltage has rotated to the position OG, the generator and a-c. circuit voltages are exactly 180 degrees out of phase so that the synchronizing voltage, CG, is maximum and thereby continues to hold the armature I? closed. When the generator voltage has rotated to the position 0A, the synchronizing voltage CA is insufficient to hold the armature i2 closed so that if allowed sufficient time, the armature I2 will drop open to close the switch H which operates to close the synchronizing circuit and to connect the generator to the a-c. circuit. The time allowed for the armature H to drop open and close the switch H5 and for the circuit breaker 36 to close is the interval of time that the generator voltage takes to rotate from position 0A to OD, since at OD the synchronizing device would again operate to close the armature B2. The synchronizing device may be adjusted to operate between 97% and 103% of synchronous speed. In that case an incoming generator could stop accelerating at 97% speed and the circuit breaker 3i would just be closed before vector 0G reached position, OD. With the same setting if the generator were to continue accelerating it would eventually be connected to the circuit somewhere between 97 and 103% speed if conditions for synchronizing were proper once during that time interval. It thus becomes apparent that my synchronizing device will function only within a limited range of speed and frequency, and within a limited phase'difference so that the electromotive forces of the incoming generator and circuit are substantially alike in frequency and phase.

If the incoming generator voltage OG should fail to fall in phase with the a-c. circuit voltage when accelerating up to synchronous speed, then the generator will accelerate beyond synchronous speed in which case the generator voltage 0G will rotate in a counterclockwise direction. This phenomena is well known in the indicating synchronoscope art in which the needle rotation indicates slow and fast. Assume the generator is accelerating above 100% synchronous speed. Then the generator voltage 0G rotating in a counterclockwise direction will produce a synchronizing voltage which operates to close the armature I2 at point M, and hold the armature l2 closed until reaching point P. At point P the synchronizing voltage CP is insufficient to hold the armature closed so that it drops open to close the switch H5 and effect the paralleling connection of the incoming generator to the a-c circuit, Thus proper phase relation for actuating the synchronizing device may occur at 101% speed (at point P) and the paralleling effected at point C or phase coincidence of the incoming generator voltage and the a-c. circuit voltage. It is a well known fact that the generator has a longer time interval in which to synchronize between 102% and 103% synchronous speed than between 97% and 98% speed while the inrush current is substantially the same. Accordingly, the synchronizing device will operate on every 0ccasion when the proper frequency and phase relation exist and therefore functions positively.

The magnitude of the incoming generator voltage G may be adjusted in the normal manner 6 by varying the direct-current excitation to the generator. If the generator voltage were below normal value, such as equal to that of vector OF in Fig. 4, the resulting synchronizing voltage would be proportional to a voltage vector drawn from C to F, and the synchronizing device would operate at a point nearer phase coincidence than that when both generator and circuit voltages were equal. Also, if the generator voltage were above normal value, such as equal to that of vector OB, the resulting synchronizing voltage would be proportional to a voltage vector drawn from C to B, and the synchronizing device would again operate at a point nearer phase coincidence than that when both generator and circuit voltages were equal. Thus it becomes evident that my synchronizing device will operate even though the incoming generator voltage may be somewhat higher or lower than the a-c. circuit voltage.

In Fig. I have shown a conventional representation of an oscillogram of the a-c. circuit voltage, the synchronizing voltage and the generator voltage. The upper oscillographic wave 40 represents the secondary voltage of transformer (Fig. 1) which is responsive to the a-c. circuit voltage of phase be. The center wave 41 repre sents the synchronizing voltage to which the synchronizer Ill is responsive. The lower wave 42 represents the secondary voltage of transformer 34 which is responsive to the generator voltage of its phase BC during the period when the generator 30 is accelerating to synchronous speed and is synchronized with the a-c. circuit. The synchronizing voltage as previously stated corresponds to the flux produced in armature I2. The synchronizing voltage may be obtained oscillographically by connecting a high resistance (not shown) across the left side of the two windings l3 and II in Fig. 1 and taking the voltage from the right side terminals of windings I3 and ll to the oscillograph. This voltage may be considered as that induced in a winding having the same number of turns wound around the armature i2 and it is responsive to the synchronizing voltage CD of Fig. 4. Since the three waves are 5 respectively proportional to the a-c. circuit voltage 00, the synchronizing voltage CA, and the generator voltage 0G, the waves will be designated in this specification by the same names.

Obviously, if no potential transformers were used, the voltages across the windings and across their sources of alternating current would be equal to one another. At instant 43 in Fig. 5, the generator voltage 42 is in phase with the a-c. circuit voltage 40 for a very short duration of time so that the resulting synchronizing voltage is low, but the frequency or speed of the generator 30 is also low so that the synchronizer l0 maintains its armature I! in closed position. At instant H, the two voltages are 180 degrees out of phase resulting in a large synchronizing voltage equal to the sum of the circuit voltage and the generator voltage to hold the armature I2 of the synchronizer in closed position. At instant 45, the voltages are again in phase but the frequency or speed of the generator is still too low for satisfactory paralleling and the synchronizer maintains its armature I! in closed position. At instant 48, the voltages are again in phase with each other resulting in a low synchronizing voltage for a duration of time suflicient for the synchronizer Hi to drop or open its armature l2 which closes the switch I I5 and energizes electromagnet 31 to close circuit breaker 3 l Thus the generator 30 is synchronized and paralleled with the a-c. circuit and normal running operation occurs after instant 46 during which the generator voltage is always in phase with the a-c. circuit voltage.

In order to connect the generator to the a-c. circuit at exact phase coincidence 'of the generator voltage and the a-c. circuit voltage it becomes necessary to initiate the paralleling operation in advance of phase coincidence. This I accomplish by means of the device shown in Fig. 7. Inasmuch as all of the elements of this form of the invention are substantially the same as those of the form of the invention shown in Fig. l the description thereof will not be repeated and the same reference numerals will be used to designate corresponding parts. In this form of the invention, transformer 36 is connected to phase be of the a-c. circuit 9 the same as in the other form. However the transformer 35 is connected to phase AC of generator circuit I30. Also the connections of this transformer are reversed. Aside from the fact that a circuit breaker is utilized which has an appreciable time lag the other elements and their manner of connection are the same.

In Fig. 8 I have shown voltage vectors of the A. C. circuit and generator circuit entering into the operation of the form of the invention shown in Fig. 7. In Fig. 8, E-bc represents the phase voltage from b to c of the a-c. circuit shown in Fig. 7, and E--ca; and Eab represent the phase voltages of the remaining circuit phases. Eg-BC represents the generator voltage of phase BC, while Eg-CA represents the generator voltage of phase CA, but connected to the synchronizing device in reversed direction. Thus the windings l3 and ll, of the synchronizing device now cooperate 60 degrees in advance of their former time of operation to cause the synchronizing and paralleling operation which thereby allows additional time for the slower-acting coils and circuit breaker, or for advance synchronizing. By selecting a circuit breaker with proper time lag, the generator may be connected to the a-c. circuit at substantially synchronism.

My synchronizing device is simple in both the mechanical and electrical aspects, yet operates at a high degree of accuracy in synchronizingancl paralleling two alternating-current sources at the proper frequency and phase. My invention is very inexpensive, easily adjusted and requires the minimum of maintenance. The synchronizing device will not operate if either of its windings 13 or I4 is burned out, or if the direct-current field excitation has failed or if the generator has failed to reach substantially synchronous speed.

It will be understood that my invention is applicable to single-phase, three-phase, and other polyphase systems. It will also be understood that it is not limited to merely synchronizing and paralleling a generator to an a-c. circuit, since obviously it can also be used to synchronize two alternating circuits in an electrical network or to synchronize one generator with another generator. In many existing plants, synchronizing is obtained by the use of lamps which are subject to-unexpected bum-outs and failures. In such plants, my synchronizing device may be used to indicate the instant of synchronism so that the operator may manually close the circuit breaker when the two voltages are substantially alike in frequency and phase.

It will, of course, be understood that various changes may be made in the form, proportions and arrangement of the parts, without departing from the scope of my invention, which, generally stated, consists in a device capable of carrying out the objects above set forth and in the novel parts and combination of parts disclosed and defined in the appended claims. Further, I do not desire to limit myself to the particular connections shown and described, but aim in the appended claims to cover all modifications which are within the scope of my invention.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing three circuitous parallel magnetic paths, a winding disposed on a portion of said core forming one of said magnetic paths and responsive to one of said sources of alternating current, another winding disposed on a portion of said core forming another of said magnetic paths and responsive to the other of said sources of alternating current, an air gap in said third magnetic path, and an armature movable to close said air gap.

2. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing three circuitous parallel magnetic paths, a winding on a portion of said core forming one of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of one source of alternating current, another winding on a portion of said core forming another of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of the other source of alternating current, an air gap in said third magnetic path, and an armature movable to close said air gap.

3. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing three circuitous parallel magnetic paths, a winding on a portion of said core forming one of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of one source of alternating current, another winding on a portion of said core forming another of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of the other source of alternating current, an air gap in said third magnetic path, an armature movable to close said air gap, and circuit closing means actuated by said armature for connecting said sources of alternating current together.

4. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core having two legs, end pieces connecting said legs together, said end pieces extending outwardly beyond one leg and forming pole pieces spaced to provide an air gap therebetween, an armature adapted to extend across said pole pieces and movable to close said air gap, a winding on one of said legs energized by a voltage corresponding in frequency and phase with the voltage of one of said sources of alternating current, and another winding on said other leg, said winding being energized by 9. voltage corresponding in frequency and phase with the voltage of said other source of alternating current.

5. In a synchronizing device'for use in paralleling two sources of alternating current, said,

form having two outside legs, a center leg and an end piece connecting said legs together at corresponding ends, an armature adapted to bridge said outside legs and movable toward and from said center leg, a winding on one of said outside legs energized by a voltage corresponding in frequency and phase with the voltage of one of said sources of alternating currents, and another winding on said other outside leg energized by a voltage corresponding in frequency and phase with the voltage of said other source of alternating current.

6. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing three circuitous parallel magnetic paths, a winding on a portion of said core forming one of said paths and energized by a voltage corresponding in phase and frequency with the voltage of one source of alternating current, another winding on a portion ofsaid core forming another of said magnetic paths and energized by a voltage corresponding in phase and frequency with the voltage of the other source of alternating current, an air gap in said third magnetic path, and an armature movable to open and close said air gap, said windings being connected in a manner to neutralize the flux passing thru said air gap when the .voltages of said sources of alternating current are substantially alike in frequency and phase.

7. In a synchronizing device for use in paralleling two sources of polyphase alternating current,,a magnetic core providing three circuitous parallel magnetic flux paths, a winding on a portion of said core forming one of said magnetic flux paths and energized by a voltage corresponding in frequency and phase with the voltage of a phase of one source of alternating current, another winding on a portion of said core forming another of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of a phase of the other source of alternating current other than the phase corresponding with said denoted phase of the first named source, an air gap in said third magnetic path, and an armature movable to close said air gap.

8. Ina synchronizing device for use in paralleling two sources of polyphase alternating current, a magnetic core providing three circuitous parallel magnetic paths, a winding on a portion of said core forming one of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of a phase of one source of alternating current, another winding on a portion of said core forming another of said magnetic paths and energized by a voltage corresponding in frequency and phase with the voltage of the phase of the other source of alternating current leading the phase corresponding with the denoted phase of said first named source, one of said windings being connected so as to procure reversal of voltage therein, an air gap in said third magnetic path, and an armature movable to close said air gap.

9. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing a magnetic circuit, an air gap in said circuit, an armature movable to close said air gap, a winding on said core energized by a voltage corresponding in frequency and phase with the voltage of one source of alternating current and providing a magnetomotive force tending to produce flux in the armature of said magnetic circuit, and another winding on said core energized by a voltage corresponding in frequency and phase with the voltage of the other source 01 alternating current, said winding providing a 5 magnetomotive force tending to produce flux in said armature, said last named winding being connected so as to cause substantially complete elimination o! flux in said armature when the voltages of said sources are substantially alike in'irequency and phase.

10. In a synchronizing device for use in paralleling two sources of alternating current, a magnetic core providing a magnetic circuit, an air gap in said circuit, an armature movable to close said air-gap, a winding on said core energized by a voltage corresponding in frequency and phase with the voltage of one source of alternating current and providing a magnetomotive force tending to produce flux in said magnetic circuit, and another winding on said core energized by a voltage corresponding in frequency and phase with the voltage of the other source of alternating current, said winding providing a magnetomotive force tending to produce flux in said armature, said last named winding being connected so as to cause substantially complete elimination of flux in said armature when the voltages of said -sources are substantially alike in frequency and phase, said core being constructed to provide another magnetic circuit in which the magnetomotive forces provided by said windings produce flux when the voltages of said sources are substantially alike in frequency and phase.

11. In a synchronizing device for use in parallellng two sources of alternating current, a magnetic core constructed with two legs each having a winding thereon, said core forming a circuitous magnetic path including an air gap, an armature movable to close said air gap, said core being constructed to form two magnetic circuits, one circuit including said legs in parallel and said air gap, and the other circuit including said legs in series, said windings being energized by voltages corresponding in frequency and phase with the voltages of said sources of alternating current and being connected to produce flux thru said first named magnetic circuit when the voltages of said sources differ in frequency or phase, and to produce flux in said second-named circuit when the voltages of said sources of alternating current are substantially alike in frequency and phase.

12. In a system of the class described wherein two sources of polyphase alternating electrometive force are to be connected together, means for connecting said sources, and means for controlling the closing of said connecting means comprising a magnetic core having two legs and an armature, a winding on one of said legs responsive to a certain phase voltage of one of said sources, a second winding on the remaining leg responsive to a different phase voltage of the second source, one of said phase voltages being in advance phase position with respect to the other phase voltage whereby the said armature operates in advance of phase coincidence for starting the connecting operation of said connecting means.

13. A synchronizer for paralleling two sources of alternating current comprising a magnetic core having at least two legs and an armature, a winding on one of said legs responsive to one of said sources of alternating current, a second winding on another leg responsive to the other of said sources of alternating current, an electric circuit controlled by said armature for connecting the sources of alternating current together, said circuit being rendered operable upon the resultant flux through said armature approaching zero.

' EDWIN W. SWANSON. 

